A Comprehensive Plan of Action on Climate Change

Threat to global food supply makes comprehensive action imperative

Climate change is strongly affecting the Arctic and the resulting changes to the polar vortex and jet stream are in turn contributing to extreme weather in many places, followed by crop loss at a huge scale.

The U.N. Food and Agriculture Organization (FAO) said in a September 6, 2012, forecast that continued deterioration of cereal crop prospects over the past two months, due to unfavourable weather conditions in a number of major producing regions, has led to a sharp cut in FAO’s world production forecast since the previous report in July.

The bad news continues: Based on the latest indications, global cereal production would not be sufficient to cover fully the expected utilization in the 2012/13 marketing season, pointing to a larger drawdown of global cereal stocks than earlier anticipated. Among the major cereals, maize and wheat were the most affected by the worsening of weather conditions.

The image below is interactive at the original post and shows the FAO Food Price Index (Cereals), up to and including August 2012.

from: Threat to global food supply makes comprehensive action imperative

Apart from crop yield, extreme weather is also affecting soils in various ways. Sustained drought can cause soils to lose much of their vegetation, making them more exposed to erosion by wind, while the occasional storms, flooding and torrential rain further contribute to erosion. Higher areas, such as hills, will be particularly vulnerable, but even in valleys a lack of trees and excessive irrigation can cause the water table to rise, bringing salt to the surface.

Fish are also under threat, in part due to ocean acidification. Of the carbon dioxide we're releasing into the atmosphere, about a third is (still) being absorbed by the oceans. Dr. Richard Feely, from NOAA’s Pacific Marine Environmental Laboratory, explains that this has caused, over the last 200 years or so, about a 30% increase in the overall acidity of the oceans. This affects species that depend on a shell to survive. Studies by Baumann (2011) and Frommel (2011) indicate further that fish, in their egg and larval life stages, are seriously threatened by ocean acidification. This, in addition to warming seawater, overfishing, pollution and eutrification (dead zones), causes fish to lose habitat and is threatening major fish stock collapse.

Without action, this situation can only be expected to deteriorate further, while ocean acidification is irreversible on timescales of at least tens of thousands of years. This means that, to save many marine species from extinction, geoengineering must be accepted as an essential part of the much-needed comprehensive plan of action.

Similarly, Arctic waters will continue to be exposed to warm water, causing further sea ice decline unless comprehensive action is taken that includes geoengineering methods to cool the Arctic. The threat that huge amounts of methane will be released from the warming Arctic seabed makes it imperative to prepare geo-engineering methods to respond to this threat and be ready for rapid deployment soon.

How to avert an intensifying food crisis

As extreme weather intensifies, the food crisis intensifies. Storms and floods do damage to crops and cause erosion of fertile topsoil, in turn causing further crop loss. Similarly, heatwaves, storms and wildfires do damage to crops and cause topsoil to be blown away, thus also causing erosion and further crop loss. Furthermore, they cause soot, dust and volitale organic compounds to settle on snow and ice, causing albdeo loss and further decline of snow and ice cover.

Extreme weather intensifies as the Arctic warms and the polar vortex and jet stream weaken, which is fueled by accelerated warming in the Arctic. There are at least ten feedbacks that contribute to further acceleration of warming in the Arctic and without action the situation looks set to spiral away into runaway global warming, as illustrated by the image below.

Diagram of Doom, with Comprehensive Plan of Action added  (credit: Sam Carana, October 9, 2012)

To avert an intensifying global food crisis, a comprehensive plan of action is needed, as also indicated on the image. Such a plan should be comprehensive and consider action in the Arctic such as wetland management, ice thickening and methane management (methane removal through decomposition, capture and possibly extraction).

A Comprehensive Plan of Action on Climate Change

A Comprehensive Plan of Action on Climate Change needs to include policies to achieve a sustainable economy, as well as adaptation policies.

Such a comprehensive plan is best endorsed globally, e.g. through an international agreement building on the Kyoto Protocol and the Montreal Accord. At the same time, the specific policies are best decided and implemented locally, e.g. by insisting that each nation reduces its CO2 emissions by a set annual percentage, and additionally removes a set annual amount of CO2 from the atmosphere and the oceans, followed by sequestration, proportionally to its current emissions.

Policy goals are most effectively achieved when policies are implemented locally and independently, with separate policies each addressing a specific shift that is needed in order to reach agreed targets. Each nation can work out what policies best fit their circumstances, as long as they each independently achieve agreed targets.

Cuts in CO2 emissions of 80% by 2020 can be achieved by implementing local policies focusing on specific sectors (such as energy production, transport, land use, waste, forestry, buildings, etc).

As an example, each nation could add fees on jetfuel. Where an airplane lands that comes from a nation that has failed to add sufficient fees, the nation where the airplane lands could impose supplementary fees and use the revenues to support methods that capture CO2 directly from ambient air. Such supplementary fees should be allowed to be imposed under international trade rules.

Some policies will need to continue beyond 2020, in order to bring down levels of greenhouse gases in the atmosphere to their pre-industrial levels this century, i.e. getting CO2 in the atmosphere back to 280ppm, CH4 back to 700ppb and N2O back to 270ppb. Policies can be very effective when focusing on local sectors such as agriculture and buildings, while also supporting geo-engineering methods such as biochar, enhanced weathering and direct capture of carbon from ambient air.

In addition to such policies to achieve a sustainable economy and adaptation policies, further geo-engineering methods will be needed to avoid runaway warming, as indicated in the blue area of the image below.

Arctic Methane Management

At the original post, some of the areas in these images can be clicked on, for examples or more background. The box for Additional Arctic Methane Management on above image is further worked out in the image below, which highlights the need for geo-engineering methods that focus on methane, a component of the plan that needs to be given far more attention. Again, support for such methods could be agreed to proportionally to each nation's current emissions.

Arctic - red alert!

Discussion: Should patent law apply to geo-engineering?

UPDATE:  The Stratospheric Particle Injection for Climate Engineering (SPICE) project has cancelled its outdoor ‘1km testbed’ experiment.  Nature News - 15 May 2012 - by Daniel Cressey Geoengineering experiment cancelled amid patent row. Balloon-based ‘testbed’ for climate-change mitigation abandoned http://www.nature.com/news/geoengineering-experiment-cancelled-amid-patent-row-1.10645

David Keith, a Harvard University professor and an adviser on energy to Microsoft founder Bill Gates, said he and his colleagues are researching whether the federal government could ban patents in the field of solar radiation, according to a report in Scientific American.

Some of his colleagues last week traveled to Washington, D.C., where they discussed whether the U.S. Patent Office could ban patents on the technology, Keith said.

"We think it's very dangerous for these solar radiation technologies, it's dangerous to have it be privatized," Keith said. "The core technologies need to be public domain."

As suggested by Sam Carana, a declaration of emergency, as called for by the Arctic Methane Emergency Group (AMEG), could be another way to deal with this issue.

A declaration of Emergency could give governments the power to overrule patents, where they stand in the way of fast-tracking geo-engineering projects proposed under emergency rules.Thus, patents don't need to be banned, prohibited or taken away; instead, patents will continue to apply in all situations other than the emergency situation, while new patents could also continue to be lodged during the emergency period.

Even where patents are directly applicable to proposed projects, patent law would still continue to apply; the emergency rules would merely allow governments to proceed in specific situations, avoiding that projects are being held up by legal action, exorbitant prices or withholding of crucial information.

A declaration of emergency could also speed up projects by removing the need to comply with all kinds of time-consuming bureaucratic procedures, such as the need to get formal approvals and permits from various departments, etc. This brings us to the need to comply with international protocols and agreements. If declared internationally, a declaration of emergency could overrule parts of such agreements where they pose unacceptable delays and cannot be resolved through diplomacy.


The issue is also discussed here and here at the Geoengineering group at Google.

The Case for Emergency Geo-Engineering to save the Arctic from Collapse

An APPCCG Event:

The Case for Emergency Geo-Engineering to save the Arctic from Collapse

WHEN: Tuesday, 13th March, 1:00 - 2:30 pm
WHERE: Committee Room 8, House of Commons, London SW1A 0AA

Please enter by St. Stephen’s Gate, and allow about 15 minutes to pass through security.

If you would like to attend this meeting, please contact Neha Sethi at the APPCCG Secretariat on climatechangegroup@carbonneutral.com or tel: +44 (0) 20 7833 6035.

---

You are invited to attend this APPCCG event with the Arctic Methane Emergency Group (AMEG), an NGO founded in October 2011 and supported by world renowned scientists. 

AMEG will set before the APPCCG new evidence that shows that because of rising sea and air temperatures the Arctic is in a state of rapid collapse, with a high probability that the Arctic will be completely ice-free at its summer minimum as early as 2013 and having no sea-ice in the Arctic for six months of the year by 2018-20.

At the same time, thawing and release of previously frozen methane previously trapped under the Arctic sea bed and in the surrounding tundra, is also increasing alarmingly, a process that will accelerate as the Arctic sea responds to the loss of sea-ice protection. 

Evidence will be presented of what is actually happening in the Arctic, in regard to the reduction of the ice sheet, the rate of methane release and details of the basic driving mechanisms in the form of warming ocean currents and increasing solar absorption in the region.

The meeting will also focus on the possible ways of halting this process and managing the level of the solar radiation currently reaching the Arctic, and will explore the challenges inherent in applying the technology in one of the most inhospitable regions on Earth.

Panellists will include:
    •    Peter Wadhams, Professor of Ocean Physics, Cambridge
    •    John Nissen, Chairman of AMEG
    •    Stephen Salter, Professor of Engineering Design, Edinburgh

The panel discussion will be followed by a question and answer session. 

---

All Party Parliamentary Climate Change Group (APPCCG)
http://www.imeche.org/Libraries/Knowledge-Power/Update_from_the_All_Party_Parliamentary_Climate_Change_Group.sflb.ashx
http://www.carbonneutral.com/page/appccg/

For more about the
Arctic Methane Emergency Group,
visit AMEG.me:
http://ameg.me

January 2012 shows record levels of methane in the Arctic

In January 2012, methane levels in the Arctic reached levels of 1870 ppb. 

Particularly worrying is that, in the past, methane concentrations have fluctuated up and down in line with the seasons. Over the past seven months, however, methane has shown steady growth in the Arctic. Such a long continuous period of growth is unprecedented, the more so as it takes place in winter, when vegetation growth and algae bloom is minimal. The most obvious conclusion is that the methane is venting from hydrates. 

Extract from: The need for geo-engioneering

How much time is there left to act?

How much time is there left to act, before methane hydrate releases will lead to human extinction? 

by Malcolm Light, edited by Sam Carana

 

Figure 1 below looks at the temperature impact of abrupt methane releases, as measured in 2010 in Svalbard (above image). Such emissions are typically triggered by disruption of the integrity of the hydrates holding the methane.

As the red line on the graph indicates, these emissions would raise local temperatures significantly, in a matter of months, since methane has a strong greenhouse effect.

At the time, the rapid increase in methane levels alarmed scientists around the world, but NASA now regards these releases merely as a local peak event that had little impact on overall global temperatures. Even so, the Svalbard event is indicative of the local temperature impact of such emissions.

The IPCC estimates the temperature change at 2090-2099 (relative to 1980-1999) at between 1.8°C (likely range: 1.1°C to 2.9°C) and 4.0°C (likely range: 2.4°C to 6.4°C), depending on the chosen scenario.

There are several ways to project how much temperatures will rise in future. The chart below shows the global temperature rise from 1980 to 2011, using the most recent NASA data. Clearly, a simple linear extension of this trend would not suffice, as it would ignore the many feedback effects accelerating the rise.

The worst-case IPCC scenario projects a mean temperature rise that would take average global temperature beyond 20 degrees Celsius this century, an obviously catastrophic scenario. Yet, the IPCC scenarios fail to include the many feedbacks that accelerate temperature rises, such as large abrupt releases from methane hydrates. In fact, the IPCC miserably failed to warn about the dramatic loss of Arctic sea ice, as pictured on the chart below, by Wipneus based on PIOMAS data.

Mid-point IPCC projections have been incorporated in Figure 2 below for reference. The diagram also incorporates the warming impact of large methane releases, triggered by a scenario based on the data from Svalbard and by the impact of increased seismic activity in the Arctic. 

Above updated global warming extinction diagram was produced using new information from the ice cap melting curve and the measured Svalbard methane concentrations (NOAA 2011a). 

While the gradients were calculated in a different way, taking account of existing Arctic temperatures, the result is almost identical to the earlier version. Furthermore, methane would only require to have a global warming potential of 43.5 over 50 years duration (Figure 2, duration from Carana 2011g) to achieve this high temperature increase in the Arctic.  The Arctic ice cap heating curves lag behind the expected Arctic atmospheric temperature curves by some 10 to 20 years over the defined extinction period which is probably a result of the extra energy needed for  the latent heat of melting of ice as the permafrost, Greenland and Antarctic ice caps melt away (Figure 2).

It is perfectly clear from the graphs that the methane build up in the Arctic is mainly a result of increasing earthquake activity along the Gakkel Ridge caused by global warming induced worldwide expansion of the Earth’s crust due to the carbon dioxide buildup in the atmosphere which is enhanced by the heating up of the Arctic ocean due to the high global warming potential of the methane (Light 2011). This close relationship between the Gakkel Ridge earthquake activity, the destabilisation of the Arctic methane hydrates and the NASA GISS surface temperature anomalies has already been clearly demonstrated (Carana, 2011b; Light 2011).

If I was a medical doctor I would say that the patient has a terminal illness and is expected to die of an extreme fever between 2038 and 2050. There are three actions that have to be taken immediately by world governments, if there is any faint hope of preventing the final excruciating stages of death the human race will be forced to live through as we are all boiled like lobsters.

1. Developed (and some developing) countries must cut back their carbon dioxide emissions by a very large percentage (50% to 90%) by 2020 to immediately precipitate a cooling of the Earth and its crust. If this is not done the earthquake frequency and methane emissions in the Arctic will continue to  grow exponentially leading to our inexorable demise in 2038 to 2050. 
    
2. Geoengineering must be used immediately as a cooling method in the Arctic to counteract the effects of the methane buildup in the short term. However, these methods will lead to further pollution of the atmosphere in the long term and will not solve the earthquake induced  Arctic methane buildup which is going to lead to our annihilation. 
    
3. The United States and Russia must immediately develop a net of powerful radio beam frequency transmission stations around the Arctic using the critical 13.56 MHZ  beat frequency to break down the methane in the stratosphere and troposphere to nanodiamonds and hydrogen (Light 2011a) . Besides the elimination of the high global warming potential methane, the nanodiamonds may form seeds for light reflecting noctilucent clouds in the stratosphere and a light coloured energy reflecting layer when brought down to the Earth by snow and rain (Light 2011a). HAARP transmission systems are able to electronically vibrate the strong ionospheric electric current that feeds down into the polar areas and are thus the least evasive method of  directly eliminating the buildup of methane in those critical regions (Light 2011a).

References

IPCC Fourth Assessment Report on Climate Change 2007 - temperature rise projections
ipcc.ch/publications_and_data/ar4/wg1/en/spmsspm-projections-of.html

NASA global temperature data
data.giss.nasa.gov/gistemp/tabledata_v3/GLB.Ts.txt

Arctic Sea Ice yearly minimum volume, with trendline added by Wipneus, based on data by
Polar Science Center | Applied Physics Laboratory | University of Washington (2011) http://psc.apl.washington.edu/wordpress/research/projects/arctic-sea-ice-volume-anomaly/

Carana, S. (2011b), Light M.P.R. and Carana, S. (2011c)
Methane linked to seismic activity in the Arctic
arctic-news.blogspot.com/p/seismic-activity.html

Light M.P.R. (2011), Edited by Sam Carana
Use of beamed interfering radio frequency transmissions to decompose Arctic atmospheric methane clouds
arctic-news.blogspot.com/p/decomposing-atmospheric-methane.html

Carana, S. (2011g)
Runaway Global Warming
geo-engineering.blogspot.com/2011/04/runaway-global-warming.html

Hansen, J.E. (2011)
GISS Surface Temperature Analysis. NASA. Goddard Institute for Space Physics
data.giss.nasa.gov/cgibin/gistemp/do_nmap.py?year_last=2011&month_last=08&sat=4&sst=1&type=anoms&mean_gen=02&year1=2009&year2=2009&base1=1951&base2=1980&radius=1200&pol=pol

IPPC (2007)
Fourth Assessment Report on Climate Change 2007. FAO 3.1, Figure 1, WG1, Chapter 3, p. 253.
blogs.ei.colombia.edu/wp-content/uploads/2010/12/graph-2-600X422.jpg

Light M.P.R. (2011)
Global Warming
globalwarmingmlight.blogspot.com

Masters. J. (2009)
Top Climate Story of 2008
www.wunderground.com/blog/JeffMasters/comment.html?entrynum=1177

NOAA (2011a), generated ESRL/GMO – 2010, November 08, 11:12 am
Huge sudden atmospheric methane spike Arctic Svalbard (north of Norway)
The need for geo-engineering

NOAA (2011b), generated ESRL/GMO – 2011, December 14, 17:21 pm
Huge sudden methane spike recorded at Barrow (BRW), Alaska, United States.
The need for geo-engineering

Crop yields in a geoengineered climate

A research team at Stanford University, led by Dr. Julia Pongratz, finds that solar-radiation geoengineering in a high-CO2 climate generally causes crop yields to increase, largely because temperature stresses are diminished while the benefits of CO2 fertilization are retained.

The team adds that, nevertheless, possible yield losses on the local scale as well as known and unknown side effects and risks associated with geoengineering indicate that the most certain way to reduce climate risks to global food security is to reduce emissions of greenhouse gases.

Paper: Crop yields in a geoengineered climate
Press release: Geoengineering and global food supply